The present disclosure relates to a wastewater tank structure and cleaning equipment. The wastewater tank structure includes a tank body and a tank cover assembly. The tank body has an accommodation cavity therein, and an end of the tank body is formed with an opening in communication with the accommodation cavity. The tank cover assembly includes a cover body and at least one flow divider, and the cover body is disposed at an end of the tank body proximate to the opening. The flow divider is in communication with the cover body and the accommodation cavity. The flow divider is configured to divide a fluid stream flowing therethrough into a plurality of fluid streams formed into pairs having paired kinetic energies carried thereby and paired opposing flow directions, such that the kinetic energies of the pairs of fluid streams cancel out.

A robotic cleaner may include one or more driven wheels, one or more sensors configured to detect one or more features of an environment, an air jet assembly configured to generate an air jet, and a side brush, a side brush operational state of the side brush corresponding to an air jet operational state of the air jet assembly.

A robotic cleaner may include one or more driven wheels, one or more sensors configured to detect one or more features of an environment, an air jet assembly configured to generate an air jet, and a side brush, a side brush operational state of the side brush corresponding to an air jet operational state of the air jet assembly.

A cleaning system includes a docking station. The docking station includes a station suction inlet configured to be fluidly coupled to a vacuum cleaner, a station dust cup configured to be removably fluidly coupled to the docking station, where the station dust cup includes a debris cavity; an odor control assembly fluidly coupled to the station dust cup; and a station suction motor configured to cause air to flow into the station suction inlet and through the station dust cup. The station suction motor is configured to generate an airflow through the odor control assembly and into the debris cavity.

A cleaning system includes a docking station. The docking station includes a station suction inlet configured to be fluidly coupled to a vacuum cleaner, a station dust cup configured to be removably fluidly coupled to the docking station, where the station dust cup includes a debris cavity; an odor control assembly fluidly coupled to the station dust cup; and a station suction motor configured to cause air to flow into the station suction inlet and through the station dust cup. The station suction motor is configured to generate an airflow through the odor control assembly and into the debris cavity.

An autonomous cleaning robot includes a drive system to move the autonomous cleaning robot about a floor surface in a space, a cleaning system to clean a floor surface in the space as the drive system moves the autonomous cleaning robot about the floor surface, and a controller configured to execute instructions to perform one or more operations. The one or more operations include initiating a cleaning mission to clean the floor surface in the space, and transmitting a signal to control an operation of an air purifier remote from the autonomous cleaning robot as the autonomous cleaning robot performs the cleaning mission

An autonomous cleaning robot includes a drive system to move the autonomous cleaning robot about a floor surface in a space, a cleaning system to clean a floor surface in the space as the drive system moves the autonomous cleaning robot about the floor surface, and a controller configured to execute instructions to perform one or more operations. The one or more operations include initiating a cleaning mission to clean the floor surface in the space, and transmitting a signal to control an operation of an air purifier remote from the autonomous cleaning robot as the autonomous cleaning robot performs the cleaning mission

A surface cleaning device includes a nozzle and an odor dial assembly. The nozzle includes a nozzle housing and a dirty air passageway. The odor dial assembly include a fragrance member and a dial body configured to be removably coupled to the nozzle housing. The dial body at least partially defines a fragrance cavity configured to at least partially receive the fragrance member and a fragrance passageway extending therethrough. The odor dial assembly is configured to transition between a plurality of user-selectable positions to adjust an amount of fragrance particles released by the fragrance member into the dirty air passageway.

A surface cleaning device includes a nozzle and an odor dial assembly. The nozzle includes a nozzle housing and a dirty air passageway. The odor dial assembly include a fragrance member and a dial body configured to be removably coupled to the nozzle housing. The dial body at least partially defines a fragrance cavity configured to at least partially receive the fragrance member and a fragrance passageway extending therethrough. The odor dial assembly is configured to transition between a plurality of user-selectable positions to adjust an amount of fragrance particles released by the fragrance member into the dirty air passageway.

The present disclosure relates to a wastewater tank structure and cleaning equipment. The wastewater tank structure includes a tank body and a tank cover assembly. The tank body has an accommodation cavity therein, and an end of the tank body is formed with an opening in communication with the accommodation cavity. The tank cover assembly includes a cover body and at least one flow divider, and the cover body is disposed at an end of the tank body proximate to the opening. The flow divider is in communication with the cover body and the accommodation cavity. The flow divider is configured to divide a fluid stream flowing therethrough into a plurality of fluid streams formed into pairs having paired kinetic energies carried thereby and paired opposing flow directions, such that the kinetic energies of the pairs of fluid streams cancel out.